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Multi-site adaptation in the presence of infrequent recombination

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  • Rouzine, Igor M.
  • Coffin, John M.

Abstract

The adverse effect of co-inheritance linkage of a large number of sites on adaptation has been studied extensively for asexual populations. However, it is insufficiently understood for multi-site populations in the presence of recombination. In the present work, motivated by our studies of HIV evolution in infected patients, we consider a model of haploid populations with infrequent recombination. We assume that small quantities of beneficial alleles preexist at a large number of sites and neglect new mutation. Using a generalized form of the traveling wave method, we show that the effectiveness of recombination is impeded and the adaptation rate is decreased by inter-sequence correlations, arising due to the fact that some pairs of homologous sites have common ancestors existing after the onset of adaptation. As the recombination rate per individual becomes smaller, site pairs with common ancestors become more frequent, making recombination even less effective. In addition, an increasing number of sites become identical by descent across large samples of sequences, causing reversion of the direction of evolution and the loss of beneficial alleles at these sites. As a result, within a 10-fold range of the recombination rate, the average adaptation rate falls from 90% of the infinite-recombination value down to 10%. The entire transition from almost maximum to almost zero may occur at very small recombination rates. Interestingly, the strong effect of linkage on the adaptation rate is predicted in the absence of average linkage disequilibrium (Lewontin’s measure).

Suggested Citation

  • Rouzine, Igor M. & Coffin, John M., 2010. "Multi-site adaptation in the presence of infrequent recombination," Theoretical Population Biology, Elsevier, vol. 77(3), pages 189-204.
    • Handle: RePEc:eee:thpobi:v:77:y:2010:i:3:p:189-204
    DOI: 10.1016/j.tpb.2010.02.001
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    References listed on IDEAS

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    1. Peter D. Keightley & Sarah P. Otto, 2006. "Interference among deleterious mutations favours sex and recombination in finite populations," Nature, Nature, vol. 443(7107), pages 89-92, September.
    2. Pleuni S Pennings & Joachim Hermisson, 2006. "Soft Sweeps III: The Signature of Positive Selection from Recurrent Mutation," PLOS Genetics, Public Library of Science, vol. 2(12), pages 1-15, December.
    3. Andreas Jung & Reinhard Maier & Jean-Pierre Vartanian & Gennady Bocharov & Volker Jung & Ulrike Fischer & Eckart Meese & Simon Wain-Hobson & Andreas Meyerhans, 2002. "Multiply infected spleen cells in HIV patients," Nature, Nature, vol. 418(6894), pages 144-144, July.
    4. Rouzine, Igor M. & Brunet, Éric & Wilke, Claus O., 2008. "The traveling-wave approach to asexual evolution: Muller's ratchet and speed of adaptation," Theoretical Population Biology, Elsevier, vol. 73(1), pages 24-46.
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